Item description for Continuum Scale Simulation of Engineering Materials: Fundamentals - Microstructures - Process Applications by Dierk Raabe...
Everything the reader needs to know about this hot topic in materials research -- from the fundamentals to recent applications. This book addresses graduate students and professionals in materials science and engineering as well as materials-oriented physicists and mechanical engineers, providing them with information needed to judge which simulation method to use for which kind of modeling/simulation problem.
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Est. Packaging Dimensions: Length: 9.53" Width: 7.09" Height: 1.97" Weight: 4.01 lbs.
Release Date Sep 3, 2004
ISBN 3527307605 ISBN13 9783527307609
Availability 0 units.
More About Dierk Raabe
Professor Dierk Raabe received his Ph.D. (1992) and habilitation (1997) at RWTH Aachen, Germany, in the fields of Physical Metallurgy and Metal Physics. He is currently Director and Executive at the Max-Planck Institut fü r Eisenforschung, Dü sseldorf, Germany, after working some time as researcher at Carnegie Mellon University, USA, the High Magnetic Field Laboratory in Tallahassee, USA, and serving as senior researcher and lecturer at the Institut fü r Metallkunde und Metallphysik, RWTH Aachen, Germany. His research fields are computer simulation of materials, composites, textures, and micromechanics, in which he authored more than 100 papers in peer-reviewed magazines and three books. He teaches various courses on computational materials science, materials mechanics, history of metals, and textures at RWTH Aachen (Germany) and at Carnegie Mellon University Pittsburgh (USA). His work was already awarded with several prizes, among them the Adolf-Martens Award, Masing Award, Heisenberg Award, and the Leibniz Award.
Dr. Franz Roters studied Physics in Braunschweig, where he got his diploma degree in 1993. From 1994 to 1998 he was scientist at the Institute for Metal Physics and Physical Metallurgy at the RWTH Aachen. He got his PhD. degree in 1999 in the field of constitutive modelling of aluminium. From 1999 till 2000 he was researcher at the R& D centre of VAW (today Hydro Aluminium Deutschland GmbH) in Bonn. Since 2000 he is senior scientist at the Max-Planck-Institut fü r Eisenforschung in Dü sseldorf, where he is the leader of the research group “ Theory and Simulation” in the department for Microstructure Physics and Metal Forming. Dr.Roters published more than 30 papers in the field of constitutive modelling and simulation of forming. He is head of the Technical Committee “ Computersimulation” of the Deutsche Gesellschaft fü r Materialkunde e.V. (DGM).
Professor Long-Qing Chen is teaching Materials Science and Engineering at Penn State. He received his B.S. in Ceramics from Zhejiang University in China in 1982, a M.S. in Materials Science and Engineering from State University of New York at Stony Brook in 1985, and a Ph.D. degree in Materials Science and Engineering from MIT in 1990. He worked with Armen G. Khachaturyan as a postdoc at Rutgers University from 1990 to 1992. Professor Chen joined the Department of Materials Science and Engineering at Penn State as an assistant professor in 1992 and was promoted to associate professor in 1998. His main research interests include materials theory and computational materials science. Professor Chen received the Young Investigator Award from the Office of Naval Research (ONR) in 1995, the research creativity award from the National Science Foundation (NSF) in 1999, the Wilson Award for Excellence in Research in the College of Earth and Mineral Sciences in 2000, and the University Faculty Scholar Medal at Penn State in 2003.
Dr. Fré dé ric Barlat received a PhD in Mechanics from the “ Institut National Polytechnique de Grenoble, ” France, in 1984. The same year, he joined Alcoa Technical Center; Pittsburgh, Pennsylvania, USA, the research facility of Alcoa Inc. (formerly the Aluminum Company of America). Dr. Barlat is currently a technology specialist in their materials science division. He is responsible for conceptualizing, importing and implementing mathematical models that predict the mechanical behavior of materials for long-term development applications in the areas of metal plasticity, fracture and material performance. His work is used for the design of alloys and processes in support of Alcoa's major business units, including packaging, automotive and aerospace. Dr. Barlat is also an invited professor at the University of Aveiro’ s Center for Mechanical Technology and Automation, Portugal, where he directs activities on the fundamentals of plasticity and forming. He has actively participated in the scientific committees of various international conferences, has been a regular reviewer in a number of scientific journals and serves as a member of the Advisory Board of the International Journal of Plasticity. Dr. Barlat is published as an author or co-author in approximately 80 papers of peer-reviewed scientific journals and has delivered more than 60 technical presentations at conferences worldwide. In 1995, he was the honored recipient of the ASM Henry Marion Howe Medal of the Material Society for the best technical paper published in Metallurgical Transactions A. He holds three US patents with co-inventors from Alcoa Inc. and Kobe Steel, Ltd., Japan.
Dierk Raabe has an academic affiliation as follows - RWTH Aachen, Germany MPI fur Eisenforschung GmbH, Dusseldorf, Germany.
Reviews - What do customers think about Continuum Scale Simulation of Engineering Materials: Fundamentals - Microstructures - Process Applications?
Handy textbook Feb 5, 2004
This book is one of the few texts dedicated solely to computational materials sciece; exclusive of topics in computational chemistry/physics (spectroscopy, band structure, brillouin zone scattering, diffraction, etc...). As such, their is only a brief coverage of quantum mechanics and related topics such as density functional theory, quantum Monte Carlo, Green's functions, etc... This is why I gave it four stars instead of five. With this exception, the book does a great job of covering simulations across all time/spatial scales from dislocation dynamics, finite element modeling, cellular automata, etc...
This is a perfect textbook for a senior level/graduate computational materials science classes that exclude quantum mechanics. The amount of math is enough for readers to know the important equations; but there are no tedious derivations.
The book also lists important applications and publications for each type of modeling. I would not purchase this book though because it is authored in 1998, which is ancient history compared to when I am writing this review (2004)with respect to the field of computational materials science.